'\" te .\" Copyright (c) 2013 by Turbo Fredriksson . All rights reserved. .\" Copyright (c) 2019 by Delphix. All rights reserved. .\" Copyright (c) 2019 Datto Inc. .\" The contents of this file are subject to the terms of the Common Development .\" and Distribution License (the "License"). You may not use this file except .\" in compliance with the License. You can obtain a copy of the license at .\" usr/src/OPENSOLARIS.LICENSE or http://www.opensolaris.org/os/licensing. .\" .\" See the License for the specific language governing permissions and .\" limitations under the License. When distributing Covered Code, include this .\" CDDL HEADER in each file and include the License file at .\" usr/src/OPENSOLARIS.LICENSE. If applicable, add the following below this .\" CDDL HEADER, with the fields enclosed by brackets "[]" replaced with your .\" own identifying information: .\" Portions Copyright [yyyy] [name of copyright owner] .TH ZFS-MODULE-PARAMETERS 5 "Feb 15, 2019" .SH NAME zfs\-module\-parameters \- ZFS module parameters .SH DESCRIPTION .sp .LP Description of the different parameters to the ZFS module. .SS "Module parameters" .sp .LP .sp .ne 2 .na \fBdbuf_cache_max_bytes\fR (ulong) .ad .RS 12n Maximum size in bytes of the dbuf cache. When \fB0\fR this value will default to \fB1/2^dbuf_cache_shift\fR (1/32) of the target ARC size, otherwise the provided value in bytes will be used. The behavior of the dbuf cache and its associated settings can be observed via the \fB/proc/spl/kstat/zfs/dbufstats\fR kstat. .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBdbuf_metadata_cache_max_bytes\fR (ulong) .ad .RS 12n Maximum size in bytes of the metadata dbuf cache. When \fB0\fR this value will default to \fB1/2^dbuf_cache_shift\fR (1/16) of the target ARC size, otherwise the provided value in bytes will be used. The behavior of the metadata dbuf cache and its associated settings can be observed via the \fB/proc/spl/kstat/zfs/dbufstats\fR kstat. .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBdbuf_cache_hiwater_pct\fR (uint) .ad .RS 12n The percentage over \fBdbuf_cache_max_bytes\fR when dbufs must be evicted directly. .sp Default value: \fB10\fR%. .RE .sp .ne 2 .na \fBdbuf_cache_lowater_pct\fR (uint) .ad .RS 12n The percentage below \fBdbuf_cache_max_bytes\fR when the evict thread stops evicting dbufs. .sp Default value: \fB10\fR%. .RE .sp .ne 2 .na \fBdbuf_cache_shift\fR (int) .ad .RS 12n Set the size of the dbuf cache, \fBdbuf_cache_max_bytes\fR, to a log2 fraction of the target arc size. .sp Default value: \fB5\fR. .RE .sp .ne 2 .na \fBdbuf_metadata_cache_shift\fR (int) .ad .RS 12n Set the size of the dbuf metadata cache, \fBdbuf_metadata_cache_max_bytes\fR, to a log2 fraction of the target arc size. .sp Default value: \fB6\fR. .RE .sp .ne 2 .na \fBdmu_prefetch_max\fR (int) .ad .RS 12n Limit the amount we can prefetch with one call to this amount (in bytes). This helps to limit the amount of memory that can be used by prefetching. .sp Default value: \fB134,217,728\fR (128MB). .RE .sp .ne 2 .na \fBignore_hole_birth\fR (int) .ad .RS 12n This is an alias for \fBsend_holes_without_birth_time\fR. .RE .sp .ne 2 .na \fBl2arc_feed_again\fR (int) .ad .RS 12n Turbo L2ARC warm-up. When the L2ARC is cold the fill interval will be set as fast as possible. .sp Use \fB1\fR for yes (default) and \fB0\fR to disable. .RE .sp .ne 2 .na \fBl2arc_feed_min_ms\fR (ulong) .ad .RS 12n Min feed interval in milliseconds. Requires \fBl2arc_feed_again=1\fR and only applicable in related situations. .sp Default value: \fB200\fR. .RE .sp .ne 2 .na \fBl2arc_feed_secs\fR (ulong) .ad .RS 12n Seconds between L2ARC writing .sp Default value: \fB1\fR. .RE .sp .ne 2 .na \fBl2arc_headroom\fR (ulong) .ad .RS 12n How far through the ARC lists to search for L2ARC cacheable content, expressed as a multiplier of \fBl2arc_write_max\fR .sp Default value: \fB2\fR. .RE .sp .ne 2 .na \fBl2arc_headroom_boost\fR (ulong) .ad .RS 12n Scales \fBl2arc_headroom\fR by this percentage when L2ARC contents are being successfully compressed before writing. A value of 100 disables this feature. .sp Default value: \fB200\fR%. .RE .sp .ne 2 .na \fBl2arc_noprefetch\fR (int) .ad .RS 12n Do not write buffers to L2ARC if they were prefetched but not used by applications .sp Use \fB1\fR for yes (default) and \fB0\fR to disable. .RE .sp .ne 2 .na \fBl2arc_norw\fR (int) .ad .RS 12n No reads during writes .sp Use \fB1\fR for yes and \fB0\fR for no (default). .RE .sp .ne 2 .na \fBl2arc_write_boost\fR (ulong) .ad .RS 12n Cold L2ARC devices will have \fBl2arc_write_max\fR increased by this amount while they remain cold. .sp Default value: \fB8,388,608\fR. .RE .sp .ne 2 .na \fBl2arc_write_max\fR (ulong) .ad .RS 12n Max write bytes per interval .sp Default value: \fB8,388,608\fR. .RE .sp .ne 2 .na \fBmetaslab_aliquot\fR (ulong) .ad .RS 12n Metaslab granularity, in bytes. This is roughly similar to what would be referred to as the "stripe size" in traditional RAID arrays. In normal operation, ZFS will try to write this amount of data to a top-level vdev before moving on to the next one. .sp Default value: \fB524,288\fR. .RE .sp .ne 2 .na \fBmetaslab_bias_enabled\fR (int) .ad .RS 12n Enable metaslab group biasing based on its vdev's over- or under-utilization relative to the pool. .sp Use \fB1\fR for yes (default) and \fB0\fR for no. .RE .sp .ne 2 .na \fBmetaslab_force_ganging\fR (ulong) .ad .RS 12n Make some blocks above a certain size be gang blocks. This option is used by the test suite to facilitate testing. .sp Default value: \fB16,777,217\fR. .RE .sp .ne 2 .na \fBzfs_keep_log_spacemaps_at_export\fR (int) .ad .RS 12n Prevent log spacemaps from being destroyed during pool exports and destroys. .sp Use \fB1\fR for yes and \fB0\fR for no (default). .RE .sp .ne 2 .na \fBzfs_metaslab_segment_weight_enabled\fR (int) .ad .RS 12n Enable/disable segment-based metaslab selection. .sp Use \fB1\fR for yes (default) and \fB0\fR for no. .RE .sp .ne 2 .na \fBzfs_metaslab_switch_threshold\fR (int) .ad .RS 12n When using segment-based metaslab selection, continue allocating from the active metaslab until \fBzfs_metaslab_switch_threshold\fR worth of buckets have been exhausted. .sp Default value: \fB2\fR. .RE .sp .ne 2 .na \fBmetaslab_debug_load\fR (int) .ad .RS 12n Load all metaslabs during pool import. .sp Use \fB1\fR for yes and \fB0\fR for no (default). .RE .sp .ne 2 .na \fBmetaslab_debug_unload\fR (int) .ad .RS 12n Prevent metaslabs from being unloaded. .sp Use \fB1\fR for yes and \fB0\fR for no (default). .RE .sp .ne 2 .na \fBmetaslab_fragmentation_factor_enabled\fR (int) .ad .RS 12n Enable use of the fragmentation metric in computing metaslab weights. .sp Use \fB1\fR for yes (default) and \fB0\fR for no. .RE .sp .ne 2 .na \fBmetaslab_df_max_search\fR (int) .ad .RS 12n Maximum distance to search forward from the last offset. Without this limit, fragmented pools can see >100,000 iterations and metaslab_block_picker() becomes the performance limiting factor on high-performance storage. With the default setting of 16MB, we typically see less than 500 iterations, even with very fragmented, ashift=9 pools. The maximum number of iterations possible is: \fBmetaslab_df_max_search / (2 * (1<> \fBzfs_arc_overflow_shift\fR". The default value of 8 causes the ARC to be considered to be overflowing if it exceeds the target size by 1/256th (0.3%) of the target size. When the ARC is overflowing, new buffer allocations are stalled until the reclaim thread catches up and the overflow condition no longer exists. .sp Default value: \fB8\fR. .RE .sp .ne 2 .na \fBzfs_arc_p_min_shift\fR (int) .ad .RS 12n If set to a non zero value, this will update arc_p_min_shift (default 4) with the new value. arc_p_min_shift is used to shift of arc_c for calculating both min and max max arc_p .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBzfs_arc_p_dampener_disable\fR (int) .ad .RS 12n Disable arc_p adapt dampener .sp Use \fB1\fR for yes (default) and \fB0\fR to disable. .RE .sp .ne 2 .na \fBzfs_arc_shrink_shift\fR (int) .ad .RS 12n If set to a non zero value, this will update arc_shrink_shift (default 7) with the new value. .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBzfs_arc_pc_percent\fR (uint) .ad .RS 12n Percent of pagecache to reclaim arc to This tunable allows ZFS arc to play more nicely with the kernel's LRU pagecache. It can guarantee that the arc size won't collapse under scanning pressure on the pagecache, yet still allows arc to be reclaimed down to zfs_arc_min if necessary. This value is specified as percent of pagecache size (as measured by NR_FILE_PAGES) where that percent may exceed 100. This only operates during memory pressure/reclaim. .sp Default value: \fB0\fR% (disabled). .RE .sp .ne 2 .na \fBzfs_arc_sys_free\fR (ulong) .ad .RS 12n The target number of bytes the ARC should leave as free memory on the system. Defaults to the larger of 1/64 of physical memory or 512K. Setting this option to a non-zero value will override the default. .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBzfs_autoimport_disable\fR (int) .ad .RS 12n Disable pool import at module load by ignoring the cache file (typically \fB/etc/zfs/zpool.cache\fR). .sp Use \fB1\fR for yes (default) and \fB0\fR for no. .RE .sp .ne 2 .na \fBzfs_checksums_per_second\fR (int) .ad .RS 12n Rate limit checksum events to this many per second. Note that this should not be set below the zed thresholds (currently 10 checksums over 10 sec) or else zed may not trigger any action. .sp Default value: 20 .RE .sp .ne 2 .na \fBzfs_commit_timeout_pct\fR (int) .ad .RS 12n This controls the amount of time that a ZIL block (lwb) will remain "open" when it isn't "full", and it has a thread waiting for it to be committed to stable storage. The timeout is scaled based on a percentage of the last lwb latency to avoid significantly impacting the latency of each individual transaction record (itx). .sp Default value: \fB5\fR%. .RE .sp .ne 2 .na \fBzfs_condense_indirect_vdevs_enable\fR (int) .ad .RS 12n Enable condensing indirect vdev mappings. When set to a non-zero value, attempt to condense indirect vdev mappings if the mapping uses more than \fBzfs_condense_min_mapping_bytes\fR bytes of memory and if the obsolete space map object uses more than \fBzfs_condense_max_obsolete_bytes\fR bytes on-disk. The condensing process is an attempt to save memory by removing obsolete mappings. .sp Default value: \fB1\fR. .RE .sp .ne 2 .na \fBzfs_condense_max_obsolete_bytes\fR (ulong) .ad .RS 12n Only attempt to condense indirect vdev mappings if the on-disk size of the obsolete space map object is greater than this number of bytes (see \fBfBzfs_condense_indirect_vdevs_enable\fR). .sp Default value: \fB1,073,741,824\fR. .RE .sp .ne 2 .na \fBzfs_condense_min_mapping_bytes\fR (ulong) .ad .RS 12n Minimum size vdev mapping to attempt to condense (see \fBzfs_condense_indirect_vdevs_enable\fR). .sp Default value: \fB131,072\fR. .RE .sp .ne 2 .na \fBzfs_dbgmsg_enable\fR (int) .ad .RS 12n Internally ZFS keeps a small log to facilitate debugging. By default the log is disabled, to enable it set this option to 1. The contents of the log can be accessed by reading the /proc/spl/kstat/zfs/dbgmsg file. Writing 0 to this proc file clears the log. .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBzfs_dbgmsg_maxsize\fR (int) .ad .RS 12n The maximum size in bytes of the internal ZFS debug log. .sp Default value: \fB4M\fR. .RE .sp .ne 2 .na \fBzfs_dbuf_state_index\fR (int) .ad .RS 12n This feature is currently unused. It is normally used for controlling what reporting is available under /proc/spl/kstat/zfs. .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBzfs_deadman_enabled\fR (int) .ad .RS 12n When a pool sync operation takes longer than \fBzfs_deadman_synctime_ms\fR milliseconds, or when an individual I/O takes longer than \fBzfs_deadman_ziotime_ms\fR milliseconds, then the operation is considered to be "hung". If \fBzfs_deadman_enabled\fR is set then the deadman behavior is invoked as described by the \fBzfs_deadman_failmode\fR module option. By default the deadman is enabled and configured to \fBwait\fR which results in "hung" I/Os only being logged. The deadman is automatically disabled when a pool gets suspended. .sp Default value: \fB1\fR. .RE .sp .ne 2 .na \fBzfs_deadman_failmode\fR (charp) .ad .RS 12n Controls the failure behavior when the deadman detects a "hung" I/O. Valid values are \fBwait\fR, \fBcontinue\fR, and \fBpanic\fR. .sp \fBwait\fR - Wait for a "hung" I/O to complete. For each "hung" I/O a "deadman" event will be posted describing that I/O. .sp \fBcontinue\fR - Attempt to recover from a "hung" I/O by re-dispatching it to the I/O pipeline if possible. .sp \fBpanic\fR - Panic the system. This can be used to facilitate an automatic fail-over to a properly configured fail-over partner. .sp Default value: \fBwait\fR. .RE .sp .ne 2 .na \fBzfs_deadman_checktime_ms\fR (int) .ad .RS 12n Check time in milliseconds. This defines the frequency at which we check for hung I/O and potentially invoke the \fBzfs_deadman_failmode\fR behavior. .sp Default value: \fB60,000\fR. .RE .sp .ne 2 .na \fBzfs_deadman_synctime_ms\fR (ulong) .ad .RS 12n Interval in milliseconds after which the deadman is triggered and also the interval after which a pool sync operation is considered to be "hung". Once this limit is exceeded the deadman will be invoked every \fBzfs_deadman_checktime_ms\fR milliseconds until the pool sync completes. .sp Default value: \fB600,000\fR. .RE .sp .ne 2 .na \fBzfs_deadman_ziotime_ms\fR (ulong) .ad .RS 12n Interval in milliseconds after which the deadman is triggered and an individual I/O operation is considered to be "hung". As long as the I/O remains "hung" the deadman will be invoked every \fBzfs_deadman_checktime_ms\fR milliseconds until the I/O completes. .sp Default value: \fB300,000\fR. .RE .sp .ne 2 .na \fBzfs_dedup_prefetch\fR (int) .ad .RS 12n Enable prefetching dedup-ed blks .sp Use \fB1\fR for yes and \fB0\fR to disable (default). .RE .sp .ne 2 .na \fBzfs_delay_min_dirty_percent\fR (int) .ad .RS 12n Start to delay each transaction once there is this amount of dirty data, expressed as a percentage of \fBzfs_dirty_data_max\fR. This value should be >= zfs_vdev_async_write_active_max_dirty_percent. See the section "ZFS TRANSACTION DELAY". .sp Default value: \fB60\fR%. .RE .sp .ne 2 .na \fBzfs_delay_scale\fR (int) .ad .RS 12n This controls how quickly the transaction delay approaches infinity. Larger values cause longer delays for a given amount of dirty data. .sp For the smoothest delay, this value should be about 1 billion divided by the maximum number of operations per second. This will smoothly handle between 10x and 1/10th this number. .sp See the section "ZFS TRANSACTION DELAY". .sp Note: \fBzfs_delay_scale\fR * \fBzfs_dirty_data_max\fR must be < 2^64. .sp Default value: \fB500,000\fR. .RE .sp .ne 2 .na \fBzfs_slow_io_events_per_second\fR (int) .ad .RS 12n Rate limit delay zevents (which report slow I/Os) to this many per second. .sp Default value: 20 .RE .sp .ne 2 .na \fBzfs_unflushed_max_mem_amt\fR (ulong) .ad .RS 12n Upper-bound limit for unflushed metadata changes to be held by the log spacemap in memory (in bytes). .sp Default value: \fB1,073,741,824\fR (1GB). .RE .sp .ne 2 .na \fBzfs_unflushed_max_mem_ppm\fR (ulong) .ad .RS 12n Percentage of the overall system memory that ZFS allows to be used for unflushed metadata changes by the log spacemap. (value is calculated over 1000000 for finer granularity). .sp Default value: \fB1000\fR (which is divided by 1000000, resulting in the limit to be \fB0.1\fR% of memory) .RE .sp .ne 2 .na \fBzfs_unflushed_log_block_max\fR (ulong) .ad .RS 12n Describes the maximum number of log spacemap blocks allowed for each pool. The default value of 262144 means that the space in all the log spacemaps can add up to no more than 262144 blocks (which means 32GB of logical space before compression and ditto blocks, assuming that blocksize is 128k). .sp This tunable is important because it involves a trade-off between import time after an unclean export and the frequency of flushing metaslabs. The higher this number is, the more log blocks we allow when the pool is active which means that we flush metaslabs less often and thus decrease the number of I/Os for spacemap updates per TXG. At the same time though, that means that in the event of an unclean export, there will be more log spacemap blocks for us to read, inducing overhead in the import time of the pool. The lower the number, the amount of flushing increases destroying log blocks quicker as they become obsolete faster, which leaves less blocks to be read during import time after a crash. .sp Each log spacemap block existing during pool import leads to approximately one extra logical I/O issued. This is the reason why this tunable is exposed in terms of blocks rather than space used. .sp Default value: \fB262144\fR (256K). .RE .sp .ne 2 .na \fBzfs_unflushed_log_block_min\fR (ulong) .ad .RS 12n If the number of metaslabs is small and our incoming rate is high, we could get into a situation that we are flushing all our metaslabs every TXG. Thus we always allow at least this many log blocks. .sp Default value: \fB1000\fR. .RE .sp .ne 2 .na \fBzfs_unflushed_log_block_pct\fR (ulong) .ad .RS 12n Tunable used to determine the number of blocks that can be used for the spacemap log, expressed as a percentage of the total number of metaslabs in the pool. .sp Default value: \fB400\fR (read as \fB400\fR% - meaning that the number of log spacemap blocks are capped at 4 times the number of metaslabs in the pool). .RE .sp .ne 2 .na \fBzfs_unlink_suspend_progress\fR (uint) .ad .RS 12n When enabled, files will not be asynchronously removed from the list of pending unlinks and the space they consume will be leaked. Once this option has been disabled and the dataset is remounted, the pending unlinks will be processed and the freed space returned to the pool. This option is used by the test suite to facilitate testing. .sp Uses \fB0\fR (default) to allow progress and \fB1\fR to pause progress. .RE .sp .ne 2 .na \fBzfs_delete_blocks\fR (ulong) .ad .RS 12n This is the used to define a large file for the purposes of delete. Files containing more than \fBzfs_delete_blocks\fR will be deleted asynchronously while smaller files are deleted synchronously. Decreasing this value will reduce the time spent in an unlink(2) system call at the expense of a longer delay before the freed space is available. .sp Default value: \fB20,480\fR. .RE .sp .ne 2 .na \fBzfs_dirty_data_max\fR (int) .ad .RS 12n Determines the dirty space limit in bytes. Once this limit is exceeded, new writes are halted until space frees up. This parameter takes precedence over \fBzfs_dirty_data_max_percent\fR. See the section "ZFS TRANSACTION DELAY". .sp Default value: \fB10\fR% of physical RAM, capped at \fBzfs_dirty_data_max_max\fR. .RE .sp .ne 2 .na \fBzfs_dirty_data_max_max\fR (int) .ad .RS 12n Maximum allowable value of \fBzfs_dirty_data_max\fR, expressed in bytes. This limit is only enforced at module load time, and will be ignored if \fBzfs_dirty_data_max\fR is later changed. This parameter takes precedence over \fBzfs_dirty_data_max_max_percent\fR. See the section "ZFS TRANSACTION DELAY". .sp Default value: \fB25\fR% of physical RAM. .RE .sp .ne 2 .na \fBzfs_dirty_data_max_max_percent\fR (int) .ad .RS 12n Maximum allowable value of \fBzfs_dirty_data_max\fR, expressed as a percentage of physical RAM. This limit is only enforced at module load time, and will be ignored if \fBzfs_dirty_data_max\fR is later changed. The parameter \fBzfs_dirty_data_max_max\fR takes precedence over this one. See the section "ZFS TRANSACTION DELAY". .sp Default value: \fB25\fR%. .RE .sp .ne 2 .na \fBzfs_dirty_data_max_percent\fR (int) .ad .RS 12n Determines the dirty space limit, expressed as a percentage of all memory. Once this limit is exceeded, new writes are halted until space frees up. The parameter \fBzfs_dirty_data_max\fR takes precedence over this one. See the section "ZFS TRANSACTION DELAY". .sp Default value: \fB10\fR%, subject to \fBzfs_dirty_data_max_max\fR. .RE .sp .ne 2 .na \fBzfs_dirty_data_sync_percent\fR (int) .ad .RS 12n Start syncing out a transaction group if there's at least this much dirty data as a percentage of \fBzfs_dirty_data_max\fR. This should be less than \fBzfs_vdev_async_write_active_min_dirty_percent\fR. .sp Default value: \fB20\fR% of \fBzfs_dirty_data_max\fR. .RE .sp .ne 2 .na \fBzfs_fletcher_4_impl\fR (string) .ad .RS 12n Select a fletcher 4 implementation. .sp Supported selectors are: \fBfastest\fR, \fBscalar\fR, \fBsse2\fR, \fBssse3\fR, \fBavx2\fR, \fBavx512f\fR, and \fBaarch64_neon\fR. All of the selectors except \fBfastest\fR and \fBscalar\fR require instruction set extensions to be available and will only appear if ZFS detects that they are present at runtime. If multiple implementations of fletcher 4 are available, the \fBfastest\fR will be chosen using a micro benchmark. Selecting \fBscalar\fR results in the original, CPU based calculation, being used. Selecting any option other than \fBfastest\fR and \fBscalar\fR results in vector instructions from the respective CPU instruction set being used. .sp Default value: \fBfastest\fR. .RE .sp .ne 2 .na \fBzfs_free_bpobj_enabled\fR (int) .ad .RS 12n Enable/disable the processing of the free_bpobj object. .sp Default value: \fB1\fR. .RE .sp .ne 2 .na \fBzfs_async_block_max_blocks\fR (ulong) .ad .RS 12n Maximum number of blocks freed in a single txg. .sp Default value: \fB100,000\fR. .RE .sp .ne 2 .na \fBzfs_override_estimate_recordsize\fR (ulong) .ad .RS 12n Record size calculation override for zfs send estimates. .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBzfs_vdev_async_read_max_active\fR (int) .ad .RS 12n Maximum asynchronous read I/Os active to each device. See the section "ZFS I/O SCHEDULER". .sp Default value: \fB3\fR. .RE .sp .ne 2 .na \fBzfs_vdev_async_read_min_active\fR (int) .ad .RS 12n Minimum asynchronous read I/Os active to each device. See the section "ZFS I/O SCHEDULER". .sp Default value: \fB1\fR. .RE .sp .ne 2 .na \fBzfs_vdev_async_write_active_max_dirty_percent\fR (int) .ad .RS 12n When the pool has more than \fBzfs_vdev_async_write_active_max_dirty_percent\fR dirty data, use \fBzfs_vdev_async_write_max_active\fR to limit active async writes. If the dirty data is between min and max, the active I/O limit is linearly interpolated. See the section "ZFS I/O SCHEDULER". .sp Default value: \fB60\fR%. .RE .sp .ne 2 .na \fBzfs_vdev_async_write_active_min_dirty_percent\fR (int) .ad .RS 12n When the pool has less than \fBzfs_vdev_async_write_active_min_dirty_percent\fR dirty data, use \fBzfs_vdev_async_write_min_active\fR to limit active async writes. If the dirty data is between min and max, the active I/O limit is linearly interpolated. See the section "ZFS I/O SCHEDULER". .sp Default value: \fB30\fR%. .RE .sp .ne 2 .na \fBzfs_vdev_async_write_max_active\fR (int) .ad .RS 12n Maximum asynchronous write I/Os active to each device. See the section "ZFS I/O SCHEDULER". .sp Default value: \fB10\fR. .RE .sp .ne 2 .na \fBzfs_vdev_async_write_min_active\fR (int) .ad .RS 12n Minimum asynchronous write I/Os active to each device. See the section "ZFS I/O SCHEDULER". .sp Lower values are associated with better latency on rotational media but poorer resilver performance. The default value of 2 was chosen as a compromise. A value of 3 has been shown to improve resilver performance further at a cost of further increasing latency. .sp Default value: \fB2\fR. .RE .sp .ne 2 .na \fBzfs_vdev_initializing_max_active\fR (int) .ad .RS 12n Maximum initializing I/Os active to each device. See the section "ZFS I/O SCHEDULER". .sp Default value: \fB1\fR. .RE .sp .ne 2 .na \fBzfs_vdev_initializing_min_active\fR (int) .ad .RS 12n Minimum initializing I/Os active to each device. See the section "ZFS I/O SCHEDULER". .sp Default value: \fB1\fR. .RE .sp .ne 2 .na \fBzfs_vdev_max_active\fR (int) .ad .RS 12n The maximum number of I/Os active to each device. Ideally, this will be >= the sum of each queue's max_active. It must be at least the sum of each queue's min_active. See the section "ZFS I/O SCHEDULER". .sp Default value: \fB1,000\fR. .RE .sp .ne 2 .na \fBzfs_vdev_removal_max_active\fR (int) .ad .RS 12n Maximum removal I/Os active to each device. See the section "ZFS I/O SCHEDULER". .sp Default value: \fB2\fR. .RE .sp .ne 2 .na \fBzfs_vdev_removal_min_active\fR (int) .ad .RS 12n Minimum removal I/Os active to each device. See the section "ZFS I/O SCHEDULER". .sp Default value: \fB1\fR. .RE .sp .ne 2 .na \fBzfs_vdev_scrub_max_active\fR (int) .ad .RS 12n Maximum scrub I/Os active to each device. See the section "ZFS I/O SCHEDULER". .sp Default value: \fB2\fR. .RE .sp .ne 2 .na \fBzfs_vdev_scrub_min_active\fR (int) .ad .RS 12n Minimum scrub I/Os active to each device. See the section "ZFS I/O SCHEDULER". .sp Default value: \fB1\fR. .RE .sp .ne 2 .na \fBzfs_vdev_sync_read_max_active\fR (int) .ad .RS 12n Maximum synchronous read I/Os active to each device. See the section "ZFS I/O SCHEDULER". .sp Default value: \fB10\fR. .RE .sp .ne 2 .na \fBzfs_vdev_sync_read_min_active\fR (int) .ad .RS 12n Minimum synchronous read I/Os active to each device. See the section "ZFS I/O SCHEDULER". .sp Default value: \fB10\fR. .RE .sp .ne 2 .na \fBzfs_vdev_sync_write_max_active\fR (int) .ad .RS 12n Maximum synchronous write I/Os active to each device. See the section "ZFS I/O SCHEDULER". .sp Default value: \fB10\fR. .RE .sp .ne 2 .na \fBzfs_vdev_sync_write_min_active\fR (int) .ad .RS 12n Minimum synchronous write I/Os active to each device. See the section "ZFS I/O SCHEDULER". .sp Default value: \fB10\fR. .RE .sp .ne 2 .na \fBzfs_vdev_trim_max_active\fR (int) .ad .RS 12n Maximum trim/discard I/Os active to each device. See the section "ZFS I/O SCHEDULER". .sp Default value: \fB2\fR. .RE .sp .ne 2 .na \fBzfs_vdev_trim_min_active\fR (int) .ad .RS 12n Minimum trim/discard I/Os active to each device. See the section "ZFS I/O SCHEDULER". .sp Default value: \fB1\fR. .RE .sp .ne 2 .na \fBzfs_vdev_queue_depth_pct\fR (int) .ad .RS 12n Maximum number of queued allocations per top-level vdev expressed as a percentage of \fBzfs_vdev_async_write_max_active\fR which allows the system to detect devices that are more capable of handling allocations and to allocate more blocks to those devices. It allows for dynamic allocation distribution when devices are imbalanced as fuller devices will tend to be slower than empty devices. See also \fBzio_dva_throttle_enabled\fR. .sp Default value: \fB1000\fR%. .RE .sp .ne 2 .na \fBzfs_expire_snapshot\fR (int) .ad .RS 12n Seconds to expire .zfs/snapshot .sp Default value: \fB300\fR. .RE .sp .ne 2 .na \fBzfs_admin_snapshot\fR (int) .ad .RS 12n Allow the creation, removal, or renaming of entries in the .zfs/snapshot directory to cause the creation, destruction, or renaming of snapshots. When enabled this functionality works both locally and over NFS exports which have the 'no_root_squash' option set. This functionality is disabled by default. .sp Use \fB1\fR for yes and \fB0\fR for no (default). .RE .sp .ne 2 .na \fBzfs_flags\fR (int) .ad .RS 12n Set additional debugging flags. The following flags may be bitwise-or'd together. .sp .TS box; rB lB lB lB r l. Value Symbolic Name Description _ 1 ZFS_DEBUG_DPRINTF Enable dprintf entries in the debug log. _ 2 ZFS_DEBUG_DBUF_VERIFY * Enable extra dbuf verifications. _ 4 ZFS_DEBUG_DNODE_VERIFY * Enable extra dnode verifications. _ 8 ZFS_DEBUG_SNAPNAMES Enable snapshot name verification. _ 16 ZFS_DEBUG_MODIFY Check for illegally modified ARC buffers. _ 64 ZFS_DEBUG_ZIO_FREE Enable verification of block frees. _ 128 ZFS_DEBUG_HISTOGRAM_VERIFY Enable extra spacemap histogram verifications. _ 256 ZFS_DEBUG_METASLAB_VERIFY Verify space accounting on disk matches in-core range_trees. _ 512 ZFS_DEBUG_SET_ERROR Enable SET_ERROR and dprintf entries in the debug log. _ 1024 ZFS_DEBUG_INDIRECT_REMAP Verify split blocks created by device removal. _ 2048 ZFS_DEBUG_TRIM Verify TRIM ranges are always within the allocatable range tree. _ 4096 ZFS_DEBUG_LOG_SPACEMAP Verify that the log summary is consistent with the spacemap log and enable zfs_dbgmsgs for metaslab loading and flushing. .TE .sp * Requires debug build. .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBzfs_free_leak_on_eio\fR (int) .ad .RS 12n If destroy encounters an EIO while reading metadata (e.g. indirect blocks), space referenced by the missing metadata can not be freed. Normally this causes the background destroy to become "stalled", as it is unable to make forward progress. While in this stalled state, all remaining space to free from the error-encountering filesystem is "temporarily leaked". Set this flag to cause it to ignore the EIO, permanently leak the space from indirect blocks that can not be read, and continue to free everything else that it can. The default, "stalling" behavior is useful if the storage partially fails (i.e. some but not all i/os fail), and then later recovers. In this case, we will be able to continue pool operations while it is partially failed, and when it recovers, we can continue to free the space, with no leaks. However, note that this case is actually fairly rare. Typically pools either (a) fail completely (but perhaps temporarily, e.g. a top-level vdev going offline), or (b) have localized, permanent errors (e.g. disk returns the wrong data due to bit flip or firmware bug). In case (a), this setting does not matter because the pool will be suspended and the sync thread will not be able to make forward progress regardless. In case (b), because the error is permanent, the best we can do is leak the minimum amount of space, which is what setting this flag will do. Therefore, it is reasonable for this flag to normally be set, but we chose the more conservative approach of not setting it, so that there is no possibility of leaking space in the "partial temporary" failure case. .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBzfs_free_min_time_ms\fR (int) .ad .RS 12n During a \fBzfs destroy\fR operation using \fBfeature@async_destroy\fR a minimum of this much time will be spent working on freeing blocks per txg. .sp Default value: \fB1,000\fR. .RE .sp .ne 2 .na \fBzfs_immediate_write_sz\fR (long) .ad .RS 12n Largest data block to write to zil. Larger blocks will be treated as if the dataset being written to had the property setting \fBlogbias=throughput\fR. .sp Default value: \fB32,768\fR. .RE .sp .ne 2 .na \fBzfs_initialize_value\fR (ulong) .ad .RS 12n Pattern written to vdev free space by \fBzpool initialize\fR. .sp Default value: \fB16,045,690,984,833,335,022\fR (0xdeadbeefdeadbeee). .RE .sp .ne 2 .na \fBzfs_livelist_max_entries\fR (ulong) .ad .RS 12n The threshold size (in block pointers) at which we create a new sub-livelist. Larger sublists are more costly from a memory perspective but the fewer sublists there are, the lower the cost of insertion. .sp Default value: \fB500,000\fR. .RE .sp .ne 2 .na \fBzfs_livelist_min_percent_shared\fR (int) .ad .RS 12n If the amount of shared space between a snapshot and its clone drops below this threshold, the clone turns off the livelist and reverts to the old deletion method. This is in place because once a clone has been overwritten enough livelists no long give us a benefit. .sp Default value: \fB75\fR. .RE .sp .ne 2 .na \fBzfs_livelist_condense_new_alloc\fR (int) .ad .RS 12n Incremented each time an extra ALLOC blkptr is added to a livelist entry while it is being condensed. This option is used by the test suite to track race conditions. .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBzfs_livelist_condense_sync_cancel\fR (int) .ad .RS 12n Incremented each time livelist condensing is canceled while in spa_livelist_condense_sync. This option is used by the test suite to track race conditions. .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBzfs_livelist_condense_sync_pause\fR (int) .ad .RS 12n When set, the livelist condense process pauses indefinitely before executing the synctask - spa_livelist_condense_sync. This option is used by the test suite to trigger race conditions. .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBzfs_livelist_condense_zthr_cancel\fR (int) .ad .RS 12n Incremented each time livelist condensing is canceled while in spa_livelist_condense_cb. This option is used by the test suite to track race conditions. .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBzfs_livelist_condense_zthr_pause\fR (int) .ad .RS 12n When set, the livelist condense process pauses indefinitely before executing the open context condensing work in spa_livelist_condense_cb. This option is used by the test suite to trigger race conditions. .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBzfs_lua_max_instrlimit\fR (ulong) .ad .RS 12n The maximum execution time limit that can be set for a ZFS channel program, specified as a number of Lua instructions. .sp Default value: \fB100,000,000\fR. .RE .sp .ne 2 .na \fBzfs_lua_max_memlimit\fR (ulong) .ad .RS 12n The maximum memory limit that can be set for a ZFS channel program, specified in bytes. .sp Default value: \fB104,857,600\fR. .RE .sp .ne 2 .na \fBzfs_max_dataset_nesting\fR (int) .ad .RS 12n The maximum depth of nested datasets. This value can be tuned temporarily to fix existing datasets that exceed the predefined limit. .sp Default value: \fB50\fR. .RE .sp .ne 2 .na \fBzfs_max_log_walking\fR (ulong) .ad .RS 12n The number of past TXGs that the flushing algorithm of the log spacemap feature uses to estimate incoming log blocks. .sp Default value: \fB5\fR. .RE .sp .ne 2 .na \fBzfs_max_logsm_summary_length\fR (ulong) .ad .RS 12n Maximum number of rows allowed in the summary of the spacemap log. .sp Default value: \fB10\fR. .RE .sp .ne 2 .na \fBzfs_max_recordsize\fR (int) .ad .RS 12n We currently support block sizes from 512 bytes to 16MB. The benefits of larger blocks, and thus larger I/O, need to be weighed against the cost of COWing a giant block to modify one byte. Additionally, very large blocks can have an impact on i/o latency, and also potentially on the memory allocator. Therefore, we do not allow the recordsize to be set larger than zfs_max_recordsize (default 1MB). Larger blocks can be created by changing this tunable, and pools with larger blocks can always be imported and used, regardless of this setting. .sp Default value: \fB1,048,576\fR. .RE .sp .ne 2 .na \fBzfs_allow_redacted_dataset_mount\fR (int) .ad .RS 12n Allow datasets received with redacted send/receive to be mounted. Normally disabled because these datasets may be missing key data. .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBzfs_min_metaslabs_to_flush\fR (ulong) .ad .RS 12n Minimum number of metaslabs to flush per dirty TXG .sp Default value: \fB1\fR. .RE .sp .ne 2 .na \fBzfs_metaslab_fragmentation_threshold\fR (int) .ad .RS 12n Allow metaslabs to keep their active state as long as their fragmentation percentage is less than or equal to this value. An active metaslab that exceeds this threshold will no longer keep its active status allowing better metaslabs to be selected. .sp Default value: \fB70\fR. .RE .sp .ne 2 .na \fBzfs_mg_fragmentation_threshold\fR (int) .ad .RS 12n Metaslab groups are considered eligible for allocations if their fragmentation metric (measured as a percentage) is less than or equal to this value. If a metaslab group exceeds this threshold then it will be skipped unless all metaslab groups within the metaslab class have also crossed this threshold. .sp Default value: \fB95\fR. .RE .sp .ne 2 .na \fBzfs_mg_noalloc_threshold\fR (int) .ad .RS 12n Defines a threshold at which metaslab groups should be eligible for allocations. The value is expressed as a percentage of free space beyond which a metaslab group is always eligible for allocations. If a metaslab group's free space is less than or equal to the threshold, the allocator will avoid allocating to that group unless all groups in the pool have reached the threshold. Once all groups have reached the threshold, all groups are allowed to accept allocations. The default value of 0 disables the feature and causes all metaslab groups to be eligible for allocations. This parameter allows one to deal with pools having heavily imbalanced vdevs such as would be the case when a new vdev has been added. Setting the threshold to a non-zero percentage will stop allocations from being made to vdevs that aren't filled to the specified percentage and allow lesser filled vdevs to acquire more allocations than they otherwise would under the old \fBzfs_mg_alloc_failures\fR facility. .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBzfs_ddt_data_is_special\fR (int) .ad .RS 12n If enabled, ZFS will place DDT data into the special allocation class. .sp Default value: \fB1\fR. .RE .sp .ne 2 .na \fBzfs_user_indirect_is_special\fR (int) .ad .RS 12n If enabled, ZFS will place user data (both file and zvol) indirect blocks into the special allocation class. .sp Default value: \fB1\fR. .RE .sp .ne 2 .na \fBzfs_multihost_history\fR (int) .ad .RS 12n Historical statistics for the last N multihost updates will be available in \fB/proc/spl/kstat/zfs//multihost\fR .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBzfs_multihost_interval\fR (ulong) .ad .RS 12n Used to control the frequency of multihost writes which are performed when the \fBmultihost\fR pool property is on. This is one factor used to determine the length of the activity check during import. .sp The multihost write period is \fBzfs_multihost_interval / leaf-vdevs\fR milliseconds. On average a multihost write will be issued for each leaf vdev every \fBzfs_multihost_interval\fR milliseconds. In practice, the observed period can vary with the I/O load and this observed value is the delay which is stored in the uberblock. .sp Default value: \fB1000\fR. .RE .sp .ne 2 .na \fBzfs_multihost_import_intervals\fR (uint) .ad .RS 12n Used to control the duration of the activity test on import. Smaller values of \fBzfs_multihost_import_intervals\fR will reduce the import time but increase the risk of failing to detect an active pool. The total activity check time is never allowed to drop below one second. .sp On import the activity check waits a minimum amount of time determined by \fBzfs_multihost_interval * zfs_multihost_import_intervals\fR, or the same product computed on the host which last had the pool imported (whichever is greater). The activity check time may be further extended if the value of mmp delay found in the best uberblock indicates actual multihost updates happened at longer intervals than \fBzfs_multihost_interval\fR. A minimum value of \fB100ms\fR is enforced. .sp A value of 0 is ignored and treated as if it was set to 1. .sp Default value: \fB20\fR. .RE .sp .ne 2 .na \fBzfs_multihost_fail_intervals\fR (uint) .ad .RS 12n Controls the behavior of the pool when multihost write failures or delays are detected. .sp When \fBzfs_multihost_fail_intervals = 0\fR, multihost write failures or delays are ignored. The failures will still be reported to the ZED which depending on its configuration may take action such as suspending the pool or offlining a device. .sp When \fBzfs_multihost_fail_intervals > 0\fR, the pool will be suspended if \fBzfs_multihost_fail_intervals * zfs_multihost_interval\fR milliseconds pass without a successful mmp write. This guarantees the activity test will see mmp writes if the pool is imported. A value of 1 is ignored and treated as if it was set to 2. This is necessary to prevent the pool from being suspended due to normal, small I/O latency variations. .sp Default value: \fB10\fR. .RE .sp .ne 2 .na \fBzfs_no_scrub_io\fR (int) .ad .RS 12n Set for no scrub I/O. This results in scrubs not actually scrubbing data and simply doing a metadata crawl of the pool instead. .sp Use \fB1\fR for yes and \fB0\fR for no (default). .RE .sp .ne 2 .na \fBzfs_no_scrub_prefetch\fR (int) .ad .RS 12n Set to disable block prefetching for scrubs. .sp Use \fB1\fR for yes and \fB0\fR for no (default). .RE .sp .ne 2 .na \fBzfs_nocacheflush\fR (int) .ad .RS 12n Disable cache flush operations on disks when writing. Setting this will cause pool corruption on power loss if a volatile out-of-order write cache is enabled. .sp Use \fB1\fR for yes and \fB0\fR for no (default). .RE .sp .ne 2 .na \fBzfs_nopwrite_enabled\fR (int) .ad .RS 12n Enable NOP writes .sp Use \fB1\fR for yes (default) and \fB0\fR to disable. .RE .sp .ne 2 .na \fBzfs_dmu_offset_next_sync\fR (int) .ad .RS 12n Enable forcing txg sync to find holes. When enabled forces ZFS to act like prior versions when SEEK_HOLE or SEEK_DATA flags are used, which when a dnode is dirty causes txg's to be synced so that this data can be found. .sp Use \fB1\fR for yes and \fB0\fR to disable (default). .RE .sp .ne 2 .na \fBzfs_pd_bytes_max\fR (int) .ad .RS 12n The number of bytes which should be prefetched during a pool traversal (eg: \fBzfs send\fR or other data crawling operations) .sp Default value: \fB52,428,800\fR. .RE .sp .ne 2 .na \fBzfs_per_txg_dirty_frees_percent \fR (ulong) .ad .RS 12n Tunable to control percentage of dirtied indirect blocks from frees allowed into one TXG. After this threshold is crossed, additional frees will wait until the next TXG. A value of zero will disable this throttle. .sp Default value: \fB5\fR, set to \fB0\fR to disable. .RE .sp .ne 2 .na \fBzfs_prefetch_disable\fR (int) .ad .RS 12n This tunable disables predictive prefetch. Note that it leaves "prescient" prefetch (e.g. prefetch for zfs send) intact. Unlike predictive prefetch, prescient prefetch never issues i/os that end up not being needed, so it can't hurt performance. .sp Use \fB1\fR for yes and \fB0\fR for no (default). .RE .sp .ne 2 .na \fBzfs_qat_checksum_disable\fR (int) .ad .RS 12n This tunable disables qat hardware acceleration for sha256 checksums. It may be set after the zfs modules have been loaded to initialize the qat hardware as long as support is compiled in and the qat driver is present. .sp Use \fB1\fR for yes and \fB0\fR for no (default). .RE .sp .ne 2 .na \fBzfs_qat_compress_disable\fR (int) .ad .RS 12n This tunable disables qat hardware acceleration for gzip compression. It may be set after the zfs modules have been loaded to initialize the qat hardware as long as support is compiled in and the qat driver is present. .sp Use \fB1\fR for yes and \fB0\fR for no (default). .RE .sp .ne 2 .na \fBzfs_qat_encrypt_disable\fR (int) .ad .RS 12n This tunable disables qat hardware acceleration for AES-GCM encryption. It may be set after the zfs modules have been loaded to initialize the qat hardware as long as support is compiled in and the qat driver is present. .sp Use \fB1\fR for yes and \fB0\fR for no (default). .RE .sp .ne 2 .na \fBzfs_read_chunk_size\fR (long) .ad .RS 12n Bytes to read per chunk .sp Default value: \fB1,048,576\fR. .RE .sp .ne 2 .na \fBzfs_read_history\fR (int) .ad .RS 12n Historical statistics for the last N reads will be available in \fB/proc/spl/kstat/zfs//reads\fR .sp Default value: \fB0\fR (no data is kept). .RE .sp .ne 2 .na \fBzfs_read_history_hits\fR (int) .ad .RS 12n Include cache hits in read history .sp Use \fB1\fR for yes and \fB0\fR for no (default). .RE .sp .ne 2 .na \fBzfs_reconstruct_indirect_combinations_max\fR (int) .ad .RS 12na If an indirect split block contains more than this many possible unique combinations when being reconstructed, consider it too computationally expensive to check them all. Instead, try at most \fBzfs_reconstruct_indirect_combinations_max\fR randomly-selected combinations each time the block is accessed. This allows all segment copies to participate fairly in the reconstruction when all combinations cannot be checked and prevents repeated use of one bad copy. .sp Default value: \fB4096\fR. .RE .sp .ne 2 .na \fBzfs_recover\fR (int) .ad .RS 12n Set to attempt to recover from fatal errors. This should only be used as a last resort, as it typically results in leaked space, or worse. .sp Use \fB1\fR for yes and \fB0\fR for no (default). .RE .sp .ne 2 .na \fBzfs_removal_ignore_errors\fR (int) .ad .RS 12n .sp Ignore hard IO errors during device removal. When set, if a device encounters a hard IO error during the removal process the removal will not be cancelled. This can result in a normally recoverable block becoming permanently damaged and is not recommended. This should only be used as a last resort when the pool cannot be returned to a healthy state prior to removing the device. .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBzfs_removal_suspend_progress\fR (int) .ad .RS 12n .sp This is used by the test suite so that it can ensure that certain actions happen while in the middle of a removal. .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBzfs_remove_max_segment\fR (int) .ad .RS 12n .sp The largest contiguous segment that we will attempt to allocate when removing a device. This can be no larger than 16MB. If there is a performance problem with attempting to allocate large blocks, consider decreasing this. .sp Default value: \fB16,777,216\fR (16MB). .RE .sp .ne 2 .na \fBzfs_resilver_min_time_ms\fR (int) .ad .RS 12n Resilvers are processed by the sync thread. While resilvering it will spend at least this much time working on a resilver between txg flushes. .sp Default value: \fB3,000\fR. .RE .sp .ne 2 .na \fBzfs_scan_ignore_errors\fR (int) .ad .RS 12n If set to a nonzero value, remove the DTL (dirty time list) upon completion of a pool scan (scrub) even if there were unrepairable errors. It is intended to be used during pool repair or recovery to stop resilvering when the pool is next imported. .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBzfs_scrub_min_time_ms\fR (int) .ad .RS 12n Scrubs are processed by the sync thread. While scrubbing it will spend at least this much time working on a scrub between txg flushes. .sp Default value: \fB1,000\fR. .RE .sp .ne 2 .na \fBzfs_scan_checkpoint_intval\fR (int) .ad .RS 12n To preserve progress across reboots the sequential scan algorithm periodically needs to stop metadata scanning and issue all the verifications I/Os to disk. The frequency of this flushing is determined by the \fBzfs_scan_checkpoint_intval\fR tunable. .sp Default value: \fB7200\fR seconds (every 2 hours). .RE .sp .ne 2 .na \fBzfs_scan_fill_weight\fR (int) .ad .RS 12n This tunable affects how scrub and resilver I/O segments are ordered. A higher number indicates that we care more about how filled in a segment is, while a lower number indicates we care more about the size of the extent without considering the gaps within a segment. This value is only tunable upon module insertion. Changing the value afterwards will have no affect on scrub or resilver performance. .sp Default value: \fB3\fR. .RE .sp .ne 2 .na \fBzfs_scan_issue_strategy\fR (int) .ad .RS 12n Determines the order that data will be verified while scrubbing or resilvering. If set to \fB1\fR, data will be verified as sequentially as possible, given the amount of memory reserved for scrubbing (see \fBzfs_scan_mem_lim_fact\fR). This may improve scrub performance if the pool's data is very fragmented. If set to \fB2\fR, the largest mostly-contiguous chunk of found data will be verified first. By deferring scrubbing of small segments, we may later find adjacent data to coalesce and increase the segment size. If set to \fB0\fR, zfs will use strategy \fB1\fR during normal verification and strategy \fB2\fR while taking a checkpoint. .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBzfs_scan_legacy\fR (int) .ad .RS 12n A value of 0 indicates that scrubs and resilvers will gather metadata in memory before issuing sequential I/O. A value of 1 indicates that the legacy algorithm will be used where I/O is initiated as soon as it is discovered. Changing this value to 0 will not affect scrubs or resilvers that are already in progress. .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBzfs_scan_max_ext_gap\fR (int) .ad .RS 12n Indicates the largest gap in bytes between scrub / resilver I/Os that will still be considered sequential for sorting purposes. Changing this value will not affect scrubs or resilvers that are already in progress. .sp Default value: \fB2097152 (2 MB)\fR. .RE .sp .ne 2 .na \fBzfs_scan_mem_lim_fact\fR (int) .ad .RS 12n Maximum fraction of RAM used for I/O sorting by sequential scan algorithm. This tunable determines the hard limit for I/O sorting memory usage. When the hard limit is reached we stop scanning metadata and start issuing data verification I/O. This is done until we get below the soft limit. .sp Default value: \fB20\fR which is 5% of RAM (1/20). .RE .sp .ne 2 .na \fBzfs_scan_mem_lim_soft_fact\fR (int) .ad .RS 12n The fraction of the hard limit used to determined the soft limit for I/O sorting by the sequential scan algorithm. When we cross this limit from bellow no action is taken. When we cross this limit from above it is because we are issuing verification I/O. In this case (unless the metadata scan is done) we stop issuing verification I/O and start scanning metadata again until we get to the hard limit. .sp Default value: \fB20\fR which is 5% of the hard limit (1/20). .RE .sp .ne 2 .na \fBzfs_scan_vdev_limit\fR (int) .ad .RS 12n Maximum amount of data that can be concurrently issued at once for scrubs and resilvers per leaf device, given in bytes. .sp Default value: \fB41943040\fR. .RE .sp .ne 2 .na \fBzfs_send_corrupt_data\fR (int) .ad .RS 12n Allow sending of corrupt data (ignore read/checksum errors when sending data) .sp Use \fB1\fR for yes and \fB0\fR for no (default). .RE .sp .ne 2 .na \fBzfs_send_unmodified_spill_blocks\fR (int) .ad .RS 12n Include unmodified spill blocks in the send stream. Under certain circumstances previous versions of ZFS could incorrectly remove the spill block from an existing object. Including unmodified copies of the spill blocks creates a backwards compatible stream which will recreate a spill block if it was incorrectly removed. .sp Use \fB1\fR for yes (default) and \fB0\fR for no. .RE .sp .ne 2 .na \fBzfs_send_no_prefetch_queue_ff\fR (int) .ad .RS 12n The fill fraction of the \fBzfs send\fR internal queues. The fill fraction controls the timing with which internal threads are woken up. .sp Default value: \fB20\fR. .RE .sp .ne 2 .na \fBzfs_send_no_prefetch_queue_length\fR (int) .ad .RS 12n The maximum number of bytes allowed in \fBzfs send\fR's internal queues. .sp Default value: \fB1,048,576\fR. .RE .sp .ne 2 .na \fBzfs_send_queue_ff\fR (int) .ad .RS 12n The fill fraction of the \fBzfs send\fR prefetch queue. The fill fraction controls the timing with which internal threads are woken up. .sp Default value: \fB20\fR. .RE .sp .ne 2 .na \fBzfs_send_queue_length\fR (int) .ad .RS 12n The maximum number of bytes allowed that will be prefetched by \fBzfs send\fR. This value must be at least twice the maximum block size in use. .sp Default value: \fB16,777,216\fR. .RE .sp .ne 2 .na \fBzfs_recv_queue_ff\fR (int) .ad .RS 12n The fill fraction of the \fBzfs receive\fR queue. The fill fraction controls the timing with which internal threads are woken up. .sp Default value: \fB20\fR. .RE .sp .ne 2 .na \fBzfs_recv_queue_length\fR (int) .ad .RS 12n The maximum number of bytes allowed in the \fBzfs receive\fR queue. This value must be at least twice the maximum block size in use. .sp Default value: \fB16,777,216\fR. .RE .sp .ne 2 .na \fBzfs_override_estimate_recordsize\fR (ulong) .ad .RS 12n Setting this variable overrides the default logic for estimating block sizes when doing a zfs send. The default heuristic is that the average block size will be the current recordsize. Override this value if most data in your dataset is not of that size and you require accurate zfs send size estimates. .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBzfs_sync_pass_deferred_free\fR (int) .ad .RS 12n Flushing of data to disk is done in passes. Defer frees starting in this pass .sp Default value: \fB2\fR. .RE .sp .ne 2 .na \fBzfs_spa_discard_memory_limit\fR (int) .ad .RS 12n Maximum memory used for prefetching a checkpoint's space map on each vdev while discarding the checkpoint. .sp Default value: \fB16,777,216\fR. .RE .sp .ne 2 .na \fBzfs_special_class_metadata_reserve_pct\fR (int) .ad .RS 12n Only allow small data blocks to be allocated on the special and dedup vdev types when the available free space percentage on these vdevs exceeds this value. This ensures reserved space is available for pool meta data as the special vdevs approach capacity. .sp Default value: \fB25\fR. .RE .sp .ne 2 .na \fBzfs_sync_pass_dont_compress\fR (int) .ad .RS 12n Starting in this sync pass, we disable compression (including of metadata). With the default setting, in practice, we don't have this many sync passes, so this has no effect. .sp The original intent was that disabling compression would help the sync passes to converge. However, in practice disabling compression increases the average number of sync passes, because when we turn compression off, a lot of block's size will change and thus we have to re-allocate (not overwrite) them. It also increases the number of 128KB allocations (e.g. for indirect blocks and spacemaps) because these will not be compressed. The 128K allocations are especially detrimental to performance on highly fragmented systems, which may have very few free segments of this size, and may need to load new metaslabs to satisfy 128K allocations. .sp Default value: \fB8\fR. .RE .sp .ne 2 .na \fBzfs_sync_pass_rewrite\fR (int) .ad .RS 12n Rewrite new block pointers starting in this pass .sp Default value: \fB2\fR. .RE .sp .ne 2 .na \fBzfs_sync_taskq_batch_pct\fR (int) .ad .RS 12n This controls the number of threads used by the dp_sync_taskq. The default value of 75% will create a maximum of one thread per cpu. .sp Default value: \fB75\fR%. .RE .sp .ne 2 .na \fBzfs_trim_extent_bytes_max\fR (unsigned int) .ad .RS 12n Maximum size of TRIM command. Ranges larger than this will be split in to chunks no larger than \fBzfs_trim_extent_bytes_max\fR bytes before being issued to the device. .sp Default value: \fB134,217,728\fR. .RE .sp .ne 2 .na \fBzfs_trim_extent_bytes_min\fR (unsigned int) .ad .RS 12n Minimum size of TRIM commands. TRIM ranges smaller than this will be skipped unless they're part of a larger range which was broken in to chunks. This is done because it's common for these small TRIMs to negatively impact overall performance. This value can be set to 0 to TRIM all unallocated space. .sp Default value: \fB32,768\fR. .RE .sp .ne 2 .na \fBzfs_trim_metaslab_skip\fR (unsigned int) .ad .RS 12n Skip uninitialized metaslabs during the TRIM process. This option is useful for pools constructed from large thinly-provisioned devices where TRIM operations are slow. As a pool ages an increasing fraction of the pools metaslabs will be initialized progressively degrading the usefulness of this option. This setting is stored when starting a manual TRIM and will persist for the duration of the requested TRIM. .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBzfs_trim_queue_limit\fR (unsigned int) .ad .RS 12n Maximum number of queued TRIMs outstanding per leaf vdev. The number of concurrent TRIM commands issued to the device is controlled by the \fBzfs_vdev_trim_min_active\fR and \fBzfs_vdev_trim_max_active\fR module options. .sp Default value: \fB10\fR. .RE .sp .ne 2 .na \fBzfs_trim_txg_batch\fR (unsigned int) .ad .RS 12n The number of transaction groups worth of frees which should be aggregated before TRIM operations are issued to the device. This setting represents a trade-off between issuing larger, more efficient TRIM operations and the delay before the recently trimmed space is available for use by the device. .sp Increasing this value will allow frees to be aggregated for a longer time. This will result is larger TRIM operations and potentially increased memory usage. Decreasing this value will have the opposite effect. The default value of 32 was determined to be a reasonable compromise. .sp Default value: \fB32\fR. .RE .sp .ne 2 .na \fBzfs_txg_history\fR (int) .ad .RS 12n Historical statistics for the last N txgs will be available in \fB/proc/spl/kstat/zfs//txgs\fR .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBzfs_txg_timeout\fR (int) .ad .RS 12n Flush dirty data to disk at least every N seconds (maximum txg duration) .sp Default value: \fB5\fR. .RE .sp .ne 2 .na \fBzfs_vdev_aggregate_trim\fR (int) .ad .RS 12n Allow TRIM I/Os to be aggregated. This is normally not helpful because the extents to be trimmed will have been already been aggregated by the metaslab. This option is provided for debugging and performance analysis. .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBzfs_vdev_aggregation_limit\fR (int) .ad .RS 12n Max vdev I/O aggregation size .sp Default value: \fB1,048,576\fR. .RE .sp .ne 2 .na \fBzfs_vdev_aggregation_limit_non_rotating\fR (int) .ad .RS 12n Max vdev I/O aggregation size for non-rotating media .sp Default value: \fB131,072\fR. .RE .sp .ne 2 .na \fBzfs_vdev_cache_bshift\fR (int) .ad .RS 12n Shift size to inflate reads too .sp Default value: \fB16\fR (effectively 65536). .RE .sp .ne 2 .na \fBzfs_vdev_cache_max\fR (int) .ad .RS 12n Inflate reads smaller than this value to meet the \fBzfs_vdev_cache_bshift\fR size (default 64k). .sp Default value: \fB16384\fR. .RE .sp .ne 2 .na \fBzfs_vdev_cache_size\fR (int) .ad .RS 12n Total size of the per-disk cache in bytes. .sp Currently this feature is disabled as it has been found to not be helpful for performance and in some cases harmful. .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBzfs_vdev_mirror_rotating_inc\fR (int) .ad .RS 12n A number by which the balancing algorithm increments the load calculation for the purpose of selecting the least busy mirror member when an I/O immediately follows its predecessor on rotational vdevs for the purpose of making decisions based on load. .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBzfs_vdev_mirror_rotating_seek_inc\fR (int) .ad .RS 12n A number by which the balancing algorithm increments the load calculation for the purpose of selecting the least busy mirror member when an I/O lacks locality as defined by the zfs_vdev_mirror_rotating_seek_offset. I/Os within this that are not immediately following the previous I/O are incremented by half. .sp Default value: \fB5\fR. .RE .sp .ne 2 .na \fBzfs_vdev_mirror_rotating_seek_offset\fR (int) .ad .RS 12n The maximum distance for the last queued I/O in which the balancing algorithm considers an I/O to have locality. See the section "ZFS I/O SCHEDULER". .sp Default value: \fB1048576\fR. .RE .sp .ne 2 .na \fBzfs_vdev_mirror_non_rotating_inc\fR (int) .ad .RS 12n A number by which the balancing algorithm increments the load calculation for the purpose of selecting the least busy mirror member on non-rotational vdevs when I/Os do not immediately follow one another. .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBzfs_vdev_mirror_non_rotating_seek_inc\fR (int) .ad .RS 12n A number by which the balancing algorithm increments the load calculation for the purpose of selecting the least busy mirror member when an I/O lacks locality as defined by the zfs_vdev_mirror_rotating_seek_offset. I/Os within this that are not immediately following the previous I/O are incremented by half. .sp Default value: \fB1\fR. .RE .sp .ne 2 .na \fBzfs_vdev_read_gap_limit\fR (int) .ad .RS 12n Aggregate read I/O operations if the gap on-disk between them is within this threshold. .sp Default value: \fB32,768\fR. .RE .sp .ne 2 .na \fBzfs_vdev_scheduler\fR (charp) .ad .RS 12n Set the Linux I/O scheduler on whole disk vdevs to this scheduler. Valid options are noop, cfq, bfq & deadline .sp Default value: \fBnoop\fR. .RE .sp .ne 2 .na \fBzfs_vdev_write_gap_limit\fR (int) .ad .RS 12n Aggregate write I/O over gap .sp Default value: \fB4,096\fR. .RE .sp .ne 2 .na \fBzfs_vdev_raidz_impl\fR (string) .ad .RS 12n Parameter for selecting raidz parity implementation to use. Options marked (always) below may be selected on module load as they are supported on all systems. The remaining options may only be set after the module is loaded, as they are available only if the implementations are compiled in and supported on the running system. Once the module is loaded, the content of /sys/module/zfs/parameters/zfs_vdev_raidz_impl will show available options with the currently selected one enclosed in []. Possible options are: fastest - (always) implementation selected using built-in benchmark original - (always) original raidz implementation scalar - (always) scalar raidz implementation sse2 - implementation using SSE2 instruction set (64bit x86 only) ssse3 - implementation using SSSE3 instruction set (64bit x86 only) avx2 - implementation using AVX2 instruction set (64bit x86 only) avx512f - implementation using AVX512F instruction set (64bit x86 only) avx512bw - implementation using AVX512F & AVX512BW instruction sets (64bit x86 only) aarch64_neon - implementation using NEON (Aarch64/64 bit ARMv8 only) aarch64_neonx2 - implementation using NEON with more unrolling (Aarch64/64 bit ARMv8 only) .sp Default value: \fBfastest\fR. .RE .sp .ne 2 .na \fBzfs_zevent_cols\fR (int) .ad .RS 12n When zevents are logged to the console use this as the word wrap width. .sp Default value: \fB80\fR. .RE .sp .ne 2 .na \fBzfs_zevent_console\fR (int) .ad .RS 12n Log events to the console .sp Use \fB1\fR for yes and \fB0\fR for no (default). .RE .sp .ne 2 .na \fBzfs_zevent_len_max\fR (int) .ad .RS 12n Max event queue length. A value of 0 will result in a calculated value which increases with the number of CPUs in the system (minimum 64 events). Events in the queue can be viewed with the \fBzpool events\fR command. .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBzfs_zil_clean_taskq_maxalloc\fR (int) .ad .RS 12n The maximum number of taskq entries that are allowed to be cached. When this limit is exceeded transaction records (itxs) will be cleaned synchronously. .sp Default value: \fB1048576\fR. .RE .sp .ne 2 .na \fBzfs_zil_clean_taskq_minalloc\fR (int) .ad .RS 12n The number of taskq entries that are pre-populated when the taskq is first created and are immediately available for use. .sp Default value: \fB1024\fR. .RE .sp .ne 2 .na \fBzfs_zil_clean_taskq_nthr_pct\fR (int) .ad .RS 12n This controls the number of threads used by the dp_zil_clean_taskq. The default value of 100% will create a maximum of one thread per cpu. .sp Default value: \fB100\fR%. .RE .sp .ne 2 .na \fBzil_maxblocksize\fR (int) .ad .RS 12n This sets the maximum block size used by the ZIL. On very fragmented pools, lowering this (typically to 36KB) can improve performance. .sp Default value: \fB131072\fR (128KB). .RE .sp .ne 2 .na \fBzil_nocacheflush\fR (int) .ad .RS 12n Disable the cache flush commands that are normally sent to the disk(s) by the ZIL after an LWB write has completed. Setting this will cause ZIL corruption on power loss if a volatile out-of-order write cache is enabled. .sp Use \fB1\fR for yes and \fB0\fR for no (default). .RE .sp .ne 2 .na \fBzil_replay_disable\fR (int) .ad .RS 12n Disable intent logging replay. Can be disabled for recovery from corrupted ZIL .sp Use \fB1\fR for yes and \fB0\fR for no (default). .RE .sp .ne 2 .na \fBzil_slog_bulk\fR (ulong) .ad .RS 12n Limit SLOG write size per commit executed with synchronous priority. Any writes above that will be executed with lower (asynchronous) priority to limit potential SLOG device abuse by single active ZIL writer. .sp Default value: \fB786,432\fR. .RE .sp .ne 2 .na \fBzio_deadman_log_all\fR (int) .ad .RS 12n If non-zero, the zio deadman will produce debugging messages (see \fBzfs_dbgmsg_enable\fR) for all zios, rather than only for leaf zios possessing a vdev. This is meant to be used by developers to gain diagnostic information for hang conditions which don't involve a mutex or other locking primitive; typically conditions in which a thread in the zio pipeline is looping indefinitely. .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBzio_decompress_fail_fraction\fR (int) .ad .RS 12n If non-zero, this value represents the denominator of the probability that zfs should induce a decompression failure. For instance, for a 5% decompression failure rate, this value should be set to 20. .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBzio_slow_io_ms\fR (int) .ad .RS 12n When an I/O operation takes more than \fBzio_slow_io_ms\fR milliseconds to complete is marked as a slow I/O. Each slow I/O causes a delay zevent. Slow I/O counters can be seen with "zpool status -s". .sp Default value: \fB30,000\fR. .RE .sp .ne 2 .na \fBzio_dva_throttle_enabled\fR (int) .ad .RS 12n Throttle block allocations in the I/O pipeline. This allows for dynamic allocation distribution when devices are imbalanced. When enabled, the maximum number of pending allocations per top-level vdev is limited by \fBzfs_vdev_queue_depth_pct\fR. .sp Default value: \fB1\fR. .RE .sp .ne 2 .na \fBzio_requeue_io_start_cut_in_line\fR (int) .ad .RS 12n Prioritize requeued I/O .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBzio_taskq_batch_pct\fR (uint) .ad .RS 12n Percentage of online CPUs (or CPU cores, etc) which will run a worker thread for I/O. These workers are responsible for I/O work such as compression and checksum calculations. Fractional number of CPUs will be rounded down. .sp The default value of 75 was chosen to avoid using all CPUs which can result in latency issues and inconsistent application performance, especially when high compression is enabled. .sp Default value: \fB75\fR. .RE .sp .ne 2 .na \fBzvol_inhibit_dev\fR (uint) .ad .RS 12n Do not create zvol device nodes. This may slightly improve startup time on systems with a very large number of zvols. .sp Use \fB1\fR for yes and \fB0\fR for no (default). .RE .sp .ne 2 .na \fBzvol_major\fR (uint) .ad .RS 12n Major number for zvol block devices .sp Default value: \fB230\fR. .RE .sp .ne 2 .na \fBzvol_max_discard_blocks\fR (ulong) .ad .RS 12n Discard (aka TRIM) operations done on zvols will be done in batches of this many blocks, where block size is determined by the \fBvolblocksize\fR property of a zvol. .sp Default value: \fB16,384\fR. .RE .sp .ne 2 .na \fBzvol_prefetch_bytes\fR (uint) .ad .RS 12n When adding a zvol to the system prefetch \fBzvol_prefetch_bytes\fR from the start and end of the volume. Prefetching these regions of the volume is desirable because they are likely to be accessed immediately by \fBblkid(8)\fR or by the kernel scanning for a partition table. .sp Default value: \fB131,072\fR. .RE .sp .ne 2 .na \fBzvol_request_sync\fR (uint) .ad .RS 12n When processing I/O requests for a zvol submit them synchronously. This effectively limits the queue depth to 1 for each I/O submitter. When set to 0 requests are handled asynchronously by a thread pool. The number of requests which can be handled concurrently is controller by \fBzvol_threads\fR. .sp Default value: \fB0\fR. .RE .sp .ne 2 .na \fBzvol_threads\fR (uint) .ad .RS 12n Max number of threads which can handle zvol I/O requests concurrently. .sp Default value: \fB32\fR. .RE .sp .ne 2 .na \fBzvol_volmode\fR (uint) .ad .RS 12n Defines zvol block devices behaviour when \fBvolmode\fR is set to \fBdefault\fR. Valid values are \fB1\fR (full), \fB2\fR (dev) and \fB3\fR (none). .sp Default value: \fB1\fR. .RE .SH ZFS I/O SCHEDULER ZFS issues I/O operations to leaf vdevs to satisfy and complete I/Os. The I/O scheduler determines when and in what order those operations are issued. The I/O scheduler divides operations into five I/O classes prioritized in the following order: sync read, sync write, async read, async write, and scrub/resilver. Each queue defines the minimum and maximum number of concurrent operations that may be issued to the device. In addition, the device has an aggregate maximum, \fBzfs_vdev_max_active\fR. Note that the sum of the per-queue minimums must not exceed the aggregate maximum. If the sum of the per-queue maximums exceeds the aggregate maximum, then the number of active I/Os may reach \fBzfs_vdev_max_active\fR, in which case no further I/Os will be issued regardless of whether all per-queue minimums have been met. .sp For many physical devices, throughput increases with the number of concurrent operations, but latency typically suffers. Further, physical devices typically have a limit at which more concurrent operations have no effect on throughput or can actually cause it to decrease. .sp The scheduler selects the next operation to issue by first looking for an I/O class whose minimum has not been satisfied. Once all are satisfied and the aggregate maximum has not been hit, the scheduler looks for classes whose maximum has not been satisfied. Iteration through the I/O classes is done in the order specified above. No further operations are issued if the aggregate maximum number of concurrent operations has been hit or if there are no operations queued for an I/O class that has not hit its maximum. Every time an I/O is queued or an operation completes, the I/O scheduler looks for new operations to issue. .sp In general, smaller max_active's will lead to lower latency of synchronous operations. Larger max_active's may lead to higher overall throughput, depending on underlying storage. .sp The ratio of the queues' max_actives determines the balance of performance between reads, writes, and scrubs. E.g., increasing \fBzfs_vdev_scrub_max_active\fR will cause the scrub or resilver to complete more quickly, but reads and writes to have higher latency and lower throughput. .sp All I/O classes have a fixed maximum number of outstanding operations except for the async write class. Asynchronous writes represent the data that is committed to stable storage during the syncing stage for transaction groups. Transaction groups enter the syncing state periodically so the number of queued async writes will quickly burst up and then bleed down to zero. Rather than servicing them as quickly as possible, the I/O scheduler changes the maximum number of active async write I/Os according to the amount of dirty data in the pool. Since both throughput and latency typically increase with the number of concurrent operations issued to physical devices, reducing the burstiness in the number of concurrent operations also stabilizes the response time of operations from other -- and in particular synchronous -- queues. In broad strokes, the I/O scheduler will issue more concurrent operations from the async write queue as there's more dirty data in the pool. .sp Async Writes .sp The number of concurrent operations issued for the async write I/O class follows a piece-wise linear function defined by a few adjustable points. .nf | o---------| <-- zfs_vdev_async_write_max_active ^ | /^ | | | / | | active | / | | I/O | / | | count | / | | | / | | |-------o | | <-- zfs_vdev_async_write_min_active 0|_______^______|_________| 0% | | 100% of zfs_dirty_data_max | | | `-- zfs_vdev_async_write_active_max_dirty_percent `--------- zfs_vdev_async_write_active_min_dirty_percent .fi Until the amount of dirty data exceeds a minimum percentage of the dirty data allowed in the pool, the I/O scheduler will limit the number of concurrent operations to the minimum. As that threshold is crossed, the number of concurrent operations issued increases linearly to the maximum at the specified maximum percentage of the dirty data allowed in the pool. .sp Ideally, the amount of dirty data on a busy pool will stay in the sloped part of the function between \fBzfs_vdev_async_write_active_min_dirty_percent\fR and \fBzfs_vdev_async_write_active_max_dirty_percent\fR. If it exceeds the maximum percentage, this indicates that the rate of incoming data is greater than the rate that the backend storage can handle. In this case, we must further throttle incoming writes, as described in the next section. .SH ZFS TRANSACTION DELAY We delay transactions when we've determined that the backend storage isn't able to accommodate the rate of incoming writes. .sp If there is already a transaction waiting, we delay relative to when that transaction will finish waiting. This way the calculated delay time is independent of the number of threads concurrently executing transactions. .sp If we are the only waiter, wait relative to when the transaction started, rather than the current time. This credits the transaction for "time already served", e.g. reading indirect blocks. .sp The minimum time for a transaction to take is calculated as: .nf min_time = zfs_delay_scale * (dirty - min) / (max - dirty) min_time is then capped at 100 milliseconds. .fi .sp The delay has two degrees of freedom that can be adjusted via tunables. The percentage of dirty data at which we start to delay is defined by \fBzfs_delay_min_dirty_percent\fR. This should typically be at or above \fBzfs_vdev_async_write_active_max_dirty_percent\fR so that we only start to delay after writing at full speed has failed to keep up with the incoming write rate. The scale of the curve is defined by \fBzfs_delay_scale\fR. Roughly speaking, this variable determines the amount of delay at the midpoint of the curve. .sp .nf delay 10ms +-------------------------------------------------------------*+ | *| 9ms + *+ | *| 8ms + *+ | * | 7ms + * + | * | 6ms + * + | * | 5ms + * + | * | 4ms + * + | * | 3ms + * + | * | 2ms + (midpoint) * + | | ** | 1ms + v *** + | zfs_delay_scale ----------> ******** | 0 +-------------------------------------*********----------------+ 0% <- zfs_dirty_data_max -> 100% .fi .sp Note that since the delay is added to the outstanding time remaining on the most recent transaction, the delay is effectively the inverse of IOPS. Here the midpoint of 500us translates to 2000 IOPS. The shape of the curve was chosen such that small changes in the amount of accumulated dirty data in the first 3/4 of the curve yield relatively small differences in the amount of delay. .sp The effects can be easier to understand when the amount of delay is represented on a log scale: .sp .nf delay 100ms +-------------------------------------------------------------++ + + | | + *+ 10ms + *+ + ** + | (midpoint) ** | + | ** + 1ms + v **** + + zfs_delay_scale ----------> ***** + | **** | + **** + 100us + ** + + * + | * | + * + 10us + * + + + | | + + +--------------------------------------------------------------+ 0% <- zfs_dirty_data_max -> 100% .fi .sp Note here that only as the amount of dirty data approaches its limit does the delay start to increase rapidly. The goal of a properly tuned system should be to keep the amount of dirty data out of that range by first ensuring that the appropriate limits are set for the I/O scheduler to reach optimal throughput on the backend storage, and then by changing the value of \fBzfs_delay_scale\fR to increase the steepness of the curve.